Moving picture coding and/or decoding systems, and variable-length coding and/or decoding system

ABSTRACT

A coding and/or decoding system includes: a code-word table for storing therein a plurality of code words, which are capable of being decoded both in forward and backward directions and which are formed so that delimiters of the code words are capable of being identified by a predetermined weight of the code words, so that the code words correspond to different source symbols; an encoder for selecting code words corresponding to inputted source symbols from the code-word table; and a synchronization interval setting part for preparing coded data every predetermined interval using the code words selected by the encoder and for inserting stuffing codes capable of being decoded in the backward direction. Thus, it is possible to decrease useless bit patterns to enhance the coding efficiency by smaller amounts of calculation and storage, and to decode variable length codes both in the forward and backward directions even if the synchronization interval is set every interval using the stuffing bits.

This application is a continuation of U.S. patent application Ser. No. 09/476,117 filed Jan. 3, 2000 (now U.S. Pat. No. 6,317,461), which is a continuation of U.S. application Ser. No. 08/924,387 filed on Sep. 5, 1997 (now U.S. Pat. No. 6,104,754), which is a continuation-in-part of U.S. patent application Ser. No. 08/616,809 filed on Mar. 15, 1996 (now U.S. Pat. No. 5,852,469).

BACKGROUND OF THE INVENTION

The present invention relates generally to a variable length coding and/or decoding system used for compression coding and/or decoding moving picture signals or the like. More specifically, the invention relates to a variable length coding and/or decoding system capable of decoding both in forward and backward directions, and a recording medium for recording data or programs for use in the system.

A variable length code is a code system of a short code length on average, which is obtained by assigning a short code length of codes to a frequently appearing symbol and a long code length of codes to a rarely appearing symbol. Therefore, if a variable length code is used, the amount of data can be considerably compressed in comparison with the amount of data before being coded. As a method for forming such a variable length code, the Huffman algorithm suitable for memoryless sources is known.

In general, there is a problem in that, if an error is mixed in a variable length code due to a channel error of coded data or the like, a decoding system can not correctly decode the data due to the propagation of influence of the error after the error is mixed therein. In order to avoid this problem, there is a typical method for inserting synchronization patterns at intervals to prevent the propagation of an error when there is a possibility that the error may occur in a channel. Bit patterns, which do not appear by any combinations of variable length codes, are assigned to the synchronization patterns. According to this method, even if coded data can not be decoded due to an error occurring therein, it is possible to prevent the propagation of the error to correctly decode the coded data by finding the next synchronization pattern.

However, even if the synchronization patterns are used, the coded data can not be decoded until the next synchronization pattern is found from the position, at which the coded data can not be correctly decoded due to the error occurring therein as shown in FIG. 1A.

Therefore, there is known a method for changing the variable length codes from the usual configurations shown in FIGS. 2A through 2C to the configurations shown in FIGS. 3A through 3C to form code words, which can be decoded in a usual forward direction as well as in a backward direction as shown in FIG. 1B. Since the coded data of such code words are also readable in the backward direction, the code words can be also used for reverse reproduction in a storage medium, such as a disc memory, for storing the coded data. This variable length code, which can be decoded in the forward direction as well as in the backward direction, will be hereinafter referred to as a “reversible code”.

An example of the reversible code is disclosed in Japanese Patent Laid-Open No. 5-300027, entitled “Reversible Variable Length Coding System”. This publicly-known reversible code is a variable length code, which can also be decoded in the backward direction by adding bits to the ends of code words of a Huffman code, which is a variable code capable of being decoded in the forward direction as shown in FIGS. 2A through 2C, so that the respective code words are not coincident with other code words having longer code lengths as shown in FIGS. 3A through 3C. However, this reversible code contains many useless bits to have a long average code length since the bits are added to the ends of the code words of the variable length code, which can be decoded only in the forward direction. Consequently, the coding efficiency is considerably deteriorated in comparison with the variable length code, which can be decoded only in the forward direction.

There is also a problem in that the conventional reversible code can not be decoded in the backward direction if synchronization intervals are set every predetermined interval. For example, ITU-T H.263 (1996) can align synchronization patterns every 8 bits (=1 byte), i.e., it can set positions, at which the synchronization patterns can be inserted, every 1 byte. In order to realize such alignment of synchronization intervals, stuffing codes shown in FIG. 34 are inserted before the synchronization patterns. In such a case, in the conventional reversible codes, there is a problem in that the backward decoding can not be carried out due to the stuffing bits.

Moreover, when the reversible code is simply decoded, there is a problem in that the circuit scale and the amount of operation have to be twice as large as those in a usual decoding system for variable length codes, which can be decoded only in the forward direction, by the amount decoded in the backward direction.

There is another problem in that the conventional reversible code can not be decoded in the backward direction by syntax of input information as the case may be. For example, in the case of source symbols having syntax shown in FIG. 5A, the sign of symbol B is determined by symbol A. Coded data obtained by coding source symbols having such syntax can not be decoded in the backward direction since the symbol B can not be decoded unless the symbol A has been decoded as shown in FIG. 5B.

As a coding system used when the number of source symbols is high, there is a system using escape codes. This system using escape codes has code words corresponding to a small number of source symbols having a high appearance frequency as a code-word table, and encodes a large majority of source symbols having a low appearance frequency by the combinations of escape codes and fixed length codes. Also in this system using escape codes, there has been provided a system for applying escape codes to the prefix and suffix of a variable length code, similar to the variable length code capable of being decoded both in the forward and backward directions.

In the conventional coding and/or decoding system using escape codes, it is required to search the code-word table for the presence of code words in order to distinguish the code words existing in the code-word table from the code words to be coded using escape codes.

That is, as described above, since the conventional reversible code, i.e., the variable length code capable of being decoded both in the forward and backward directions, is formed by adding bits to the suffix of code words of a variable length code capable of being decoded only in the forward direction, there is a problem in that useless bit patterns are increased to increase an average code length, so that the coding efficiency is considerably deteriorated in comparison with the variable length code capable of being decoded only in the forward direction. In addition, if the synchronization intervals are set every predetermined intervals using stuffing bits, there is a problem in that the reversible code can not be decoded in the backward direction due to the stuffing bits. Moreover, if the reversible code is simply decoded, there is a problem in that the circuit scale and the amount of operation have to be twice as large as those in a usual decoding system for variable length codes capable of being decoded only in the forward direction, by the amount decoded in the backward direction, and there is a problem in that it is not possible to decode in the backward direction by the syntax of input information as the case may be.

SUMMARY OF THE INVENTION

It is therefore an object of the present invention to provide a moving picture decoding system which can restrain the quality of a decoded image from greatly deteriorating even if an error occurs in any portion of a code, and which can efficiently decode the code even if only a part of the code can be decoded due to the error.

According to a first aspect of the present invention, a moving picture decoding system comprises: input means for inputting a first code string arranging in order from the prefix to the suffix, and a second code string arranging in order from the suffix to the prefix in the backward direction: and decoding means for decoding the first code string in order from the prefix to the suffix and for decoding the second code string in order from suffix to prefix in the backward direction. In this system, the first code string arranging in the forward direction from the prefix to the suffix and the second row arranging in the backward direction from the suffix to the prefix are decoded. Therefore, even if an error occurs in one of the rows, the decoding can be carried out without influencing the other row.

According to a second aspect of the present invention, a moving picture decoding system comprises: input means for inputting code string which have been divided into a plurality of regions with respect to each of frames; decoding means for decoding the code string of each of the regions supplied from the input means; and rearranging means for rearranging the data of each of the regions supplied from the decoding means, in correct order. In this system, the code string wherein the regions is arranged in order of importance of the rearranged image. Therefore, even if an error occurs in a part of data, the region which has been able to be decoded is an important portion, so that it is possible to restrain the lack of the important portion of the image in comparison with the conventional system.

According to a third aspect of the present invention, the moving picture decoding system as set forth includes detection means for detecting an error with respect to the first and second code string and the coded data/signal, respectively, wherein the decoding is carried out using only the data wherein no error has been detected by the error detection means. In this system, the detection of error is carried out when the divided code string is decoded. Therefore, it is possible to form a reproduced image by means of only the correctly decoded data. It is also possible to predict and complement the data which has not been able to be decoded, by means of the correctly decoded data.

According to a fourth aspect of the present invention, the moving picture decoding system includes error detecting means for detecting an error with respect to the code string and the decoded data/signal; and predicting means for predicting the region which as not been able to be decoded, on the basis of the decoded region when an error is detected by means of the error detecting means. In this system, the regions of a higher probability of decoding in both of the code string divided into two parts, can complement the regions of a lower probability of decoding in both of the code string divided into two parts. Therefore, it is possible to predict and complement the data of the data lacking region.

According to a fifth aspect of the present invention, the moving picture decoding system as set forth in the fourth aspect includes means for rearranging and decoding regions in accordance with the region rearranging data included in the code string. In this system, the code string that the coding order has been changed in accordance with the image is decoded. Therefore, even if the data have not been able to be fully decoded due to errors, it is possible to increase the probability of decoding with respect to the important portion of the coding data.

It is another object of the present invention to provide a practical variable-length decoding system which can be decoded in either of the forward and backward directions.

Specifically, it is an object of the present invention to provide a variable-length decoding system which can be decoded in either of the forward and backward directions and wherein the number of useless bit patterns is small and the coding efficiency is high.

It is a further object of the present invention to provide a variable-length decoding system which can be decoded in either of the forward and backward directions and which is unnecessary for a great memory capacity even if the number of source symbols is great.

In order to accomplish the aforementioned and other objects, according to a sixth aspect of the present invention, a variable-length coding system which assigns code words to a plurality of source symbols, the code words having a code length in accordance with the probability of the source symbols, and which outputs as coding data, the code words corresponding to the inputted source symbols, comprises: a code-word table for storing a plurality of code words so as to correspond to the source symbols, the code words being configured so as to be able to determine the pause between codes by the weights of the code words; and coding means for selecting a code word corresponding to the inputted source symbol from the code-word table and for outputting the selected code word as coding data.

The term “weight of code word” corresponds to a hamming distance from the minimum or maximum value of the code word. When the code word is a binary code, the minimum value of the code word is “0” in all cases and the maximum value of the code word is “1” in all cases, so that the weight of the code word corresponds to the number of “ 1” or “0”. The position wherein the weight of the code word is a predetermined value indicates the pause between codes in the variable-length code.

With respect to the plurality of code words stored in the code-word table, a fixed-length code, i.e. a constant length of code, is unnecessary to be added to at least one of the prefix and suffix thereof.

In addition, unlike a code wherein bits are added to the suffix of a variable-length code decodable in only the forward direction such as reversible code disclosed in the aforementioned Japanese Patent Laid-Open, a reversible code is originally configured without the addition of excessive bits, so that it is possible to obtain a variable-length code wherein the number of useless bit patterns is small and wherein the coding efficiency is great.

Moreover, a variable-length code can be obtained in accordance with the probability of appearance of source symbols by selecting a plurality of code configuring methods and a code of the minimum average code-length from parameters, on the basis of the probability of source symbols.

According to a seventh aspect of the present invention, a variable-length decoding system which can decode in either of the forward and backward directions and which decodes a variable-length code to which synchronizing codes are inserted at regular intervals, comprises: a forward decoding means for decoding a variable-length code in the forward direction and for detecting an error of a code word of the variable-length code; a backward decoding means for decoding the variable-length code in the backward direction and for detecting an error of a code word of the variable-length code; and decoded-value deciding means for deciding a decoded value on the basis of the decoded results by the forward decoding means and the backward decoding means, wherein the decoded value at the position in which the error is detected in accordance with the results of detection of the error by the forward decoding means and the backward decoding means.

Specifically, in the decoded-value deciding means, (a) when errors have been detected by both of the forward decoding means and the backward decoding means and when the detected positions of the errors have not passed each other, only the decoded result wherein no error has not been detected, is used as the decoded value, (b) when errors have been detected by both of the forward decoding means and backward decoding means and when the detected positions of the errors have not passed each other, the decoded result wherein no error has not been detected by both of the forward decoding means and the backward decoding means, is used as the decoded value, (c) when an error has been detected by one of the forward decoding means and the backward decoding means, the decoded value with respect to the code word at the position wherein the error has been detected is abandoned, and the decoded result in the backward direction is used as the decoded value with respect to the subsequent code word, and (d) when errors have been detected with respect to the same code word by means of the forward decoding means and the backward decoding means, the decoded value with respect to the code word at the position wherein an error has been detected is abandoned, and the decoded result in the backward direction is used as the decoded value with respect to the subsequent code word.

In this variable length decoding system, when the decoded value is decided on the basis of the decoded results by the forward decoding means and the backward decoding means which use a function for detecting errors in code words of a variable-length code, it is possible to effectively decode the reversible code outputted from the aforementioned variable-length coding system, against the errors such as channel errors, by deciding the decoded value at the position wherein the errors have been detected in accordance with the detected results of errors by the forward decoding means and the backward decoding means and the backward decoding means.

According to an eighth aspect of the present invention, a variable-length decoding system which can be adapted to the variable-length coding system according to the present invention and which decodes coding data of variable-length codes decodable in either of the forward and backward directions, comprises: forward decoding means for decoding a variable-length code in the forward direction; backward decoding means for decoding a variable-length code in the backward directions; and fixed-length code decoding means for decoding a fixed-length code, wherein when specific codes (escape codes) representative of the prefix and suffix of the fixed-length code have been decoded when the variable-length code is decoded by the forward decoding means and the backward decoding means, the subsequent coding data is decoded by the fixed-length code decoding means.

According to a ninth aspect of the present invention, there is provided a variable-length decoding system which decodes coding data of a variable-length code decodable in either of the forward and backward directions. In this system, the code-length of a variable-length code is derived on the basis of the number of a predetermined “1” or “0” of the code word, and the value determined by a Pascal's triangle is assigned to the value of a joint. Then, the rank order values of different code words of the same code-length is derived by means of a directed graph wherein the arrows from each joint to the next joint correspond to “1” and “0” of the code words, and a decoded value is calculated by means of the rank order value and the directed graph.

In this variable-length decoding system, it is possible to determine the pause between the codes by the number of the weights of the code words, i.e. the code length, similar to the variable-length coding system according to the present invention. In addition, this system uses variable-length code words configured by code words decodable in either of the forward and backward directions, the value determined by a Pascal's triangle is assigned to the value of a joint, and the decoded value is calculated by the directed graph (decoding graph) wherein the arrows from each joint to the next joint corresponds to “1 ” and “0” of the code words. Therefore, it is possible to decode the variable-length code by a small memory capacity even if the number of source symbol is great.

According to a tenth aspect of the present invention, a variable-length decoding system which can be adapted to the variable-length coding system according to the present invention and wherein a moving picture decoder decodes coding data decoded into a variable-length code which can decode an orthogonal transform coefficient produced by the orthogonal transform every blocks by means of a moving picture encoder, in either of the forward and backward directions, comprises: forward decoding means for decoding a variable-length code in the forward direction; and backward decoding means for decoding a variable-length code in the backward direction, wherein when the forward decoding means decodes the variable-length code, the last of the block is determined on the basis of the appearance of a code word representative of the orthogonal transform coefficient of the last of the block, and when the backward decoding means decodes the variable-length code, the head of the block is determined by the code word representative of the last orthogonal coefficient of the last block.

In the variable-length decoding system according to the present invention, the first code-word table corresponding to the orthogonal transform coefficient other than the last of the block is configured with respect to each of the plurality of coding modes. However, the second code-word table corresponding to the orthogonal transform coefficient of the last of the block is used for the respective coding modes in common, so that it is possible to cope with the change of the code-word tables by the coding mode, and to find the pause between blocks by the appearance of the code word representative of the last orthogonal transform coefficient of the last block, so that the decoding can be syntactically in either direction.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings:

FIGS. 1A and 1B are schematic drawings, each illustrating a typical coding method for a reversible code;

FIG. 2A is a table explaining a usual variable length code;

FIG. 2B is a diagram illustrating a coding tree for decoding the usual variable length code in a forward direction;

FIG. 2C is a diagram illustrating a coding tree for decoding the usual variable length code in a backward direction;

FIG. 3A is a table explaining a conventional reversible code;

FIG. 3B is a diagram illustrating a coding tree for decoding the conventional reversible code in a forward direction;

FIG. 3c is a diagram illustrating a coding tree for decoding the conventional reversible code in a backward direction;

FIG. 4 is a diagram illustrating conventional stuffing bits;

FIGS. 5A and 5B are diagrams, each illustrating a conventional syntax of source symbols, which can not be decoded in the backward direction;

FIG. 6 is a block diagram of the first preferred embodiment of a variable length coding and/or decoding system according to the present invention;

FIG. 7 is a block diagram of a code-word table preparing part of FIG. 6;

FIG. 8 is a diagram explaining a first code-word forming method in a code-word forming part of FIG. 7;

FIGS. 9A and 9B are diagrams illustrating decoding trees in forward and backward directions, respectively, which are prepared from code words formed by the first code-word forming method;

FIG. 10 is a diagram explaining a second code-word forming method in the code-word forming part of FIG. 7;

FIG. 11 is a diagram explaining a third code-word forming method in the code-word forming part of FIG. 7;

FIG. 12A is a diagram explaining a method for setting a synchronization interval using a synchronization pattern in a synchronization interval setting part;

FIG. 12B is a diagram explaining a method for setting a synchronization interval by describing a coded amount;

FIG. 13 is a diagram illustrating a first embodiment of stuffing bits;

FIG. 14 is a diagram illustrating a second embodiment of stuffing bits;

FIGS. 15A through 15D are diagrams explaining the operation of a decoded-value determining part of FIG. 7;

FIG. 16 is a schematic block diagram of the second preferred embodiment of a moving-picture coding and/or decoding system according to the present invention;

FIGS. 17A through 17C are diagrams, each illustrating a syntax of a coded data in the second preferred embodiment of a moving-picture coding and/or decoding system according to the present invention;

FIG. 18A is a block diagram of a moving-picture multiplexing part of FIG. 16;

FIG. 18B is a block diagram of a moving-picture multiplex dividing part;

FIG. 19 is a table showing a part of a code-word table of INTRA and INTER non-LAST coefficients in the second preferred embodiments;

FIG. 20 is a table showing a part of a code-word table of INTRA and INTER non-LAST coefficients in the second preferred embodiment, which is continued from FIG. 19;

FIG. 21 is a table showing a part of a code-word table of INTRA and INTER non-LAST coefficients in the second preferred embodiment, which is continued from FIG. 20;

FIG. 22 is a table showing a first half of a code-word table of INTRA and INTER LAST coefficients in the second preferred embodiment;

FIG. 23 is a table showing a second half of a code-word table of INTRA and INTER LAST coefficients in the second preferred embodiment;

FIG. 24 is a code-word table of escape codes in the second preferred embodiment;

FIG. 25 is a diagram illustrating a coding system of code words, which are not contained in the code-word table in the second preferred embodiment;

FIG. 26 is a diagram showing the maximum zero run in a code configuration in the second preferred embodiment;

FIGS. 27(a) through 27(d) are diagrams illustrating the operation of a decoded-value determining part in the second preferred embodiment;

FIG. 28 is a block diagram of the third preferred embodiment of a variable length coding and/or decoding system according to the present invention;

FIG. 29 is a diagram explaining a first code-word forming method in a code-word forming part of FIG. 28;

FIG. 30 is a diagram explaining a second code-word forming method in the code-word forming part of FIG. 28;

FIG. 31 is a diagram of a bidirectional code-word table, which is common to a forward code-word table and a backward code word table;

FIG. 32 is a block diagram of a decoder, to which a detection part is added;

FIGS. 33(a) through 33(d) are diagrams explaining a decoding method in the third preferred embodiment;

FIGS. 34(a) and 34(b) are diagrams explaining a decoded-value determining method in a decoded-value determining part in the third preferred embodiment;

FIG. 35 is a block diagram of the fourth preferred embodiment of a variable length coding and/or decoding system according to the present invention;

FIG. 36 is a block diagram of a variable length coding part of a hierarchy of FIG. 35;

FIG. 37 is a block diagram of a variable length encoding part of a hierarchy of FIG. 35;

FIGS. 38A through 38C are diagrams illustrating examples of the data hierarchization and multiplexing in a data layering part and a multiplexing part of FIG. 35, respectively;

FIG., 39 is a diagram showing an example of a decoded-value determining method in a decoded-value determining part of FIG. 37;

FIGS. 40A and 40B are diagrams showing a first embodiment of a syntax in a moving-picture coding system in a moving-picture multiplexing part and a moving-picture multiplex dividing part when the variable length coding and/or decoding system in the fourth preferred embodiment is incorporated into the moving-picture coding and/or decoding system of FIG. 16, respectively;

FIGS. 41A and 41B are diagrams showing a second embodiment of a syntax in a moving-picture coding system in a moving-picture multiplexing part and a moving-picture multiplex dividing part when the variable length coding and/or decoding system in the fourth preferred embodiment is incorporated into the moving-picture coding and/or decoding system of FIG. 16, respectively;

FIGS. 42A and 42B are diagrams showing a third embodiment of a syntax in a moving-picture coding system in a moving-picture multiplexing part and a moving-picture multiplex dividing part when the variable length coding and/or decoding system in the fourth preferred embodiment is incorporated into the moving-picture coding and/or decoding system of FIG. 16, respectively;

FIGS. 43A and 43B are diagrams showing a fourth embodiment of a syntax in a moving-picture coding system in a moving-picture multiplexing part and a moving-picture multiplex dividing part when the variable length coding and/or decoding system in the fourth preferred embodiment is incorporated into the moving-picture coding and/or decoding system of FIG. 16, respectively;

FIG. 44 is a table showing a part of a coding table of motion vectors in the fourth preferred embodiment;

FIG. 45 is a table showing a part of a coding table of motion vectors in the fourth preferred embodiment, which is continued from FIG. 44;

FIG. 46 is a table showing a part of a coding table of motion vectors in the fourth preferred embodiment, which is continued from FIG. 45;

FIG. 47 is a table showing a part of a coding table of motion vectors in the fourth preferred embodiment, which is continued from FIG. 46;

FIG. 48 is a table showing a part of a coding table of motion vectors in the fourth preferred embodiment, which is continued from FIG. 47;

FIG. 49 is a table showing a part of a coding table of motion vectors in the fourth preferred embodiment, which is continued from FIG. 48;

FIG. 50 is a table showing a part of a coding table of motion vectors in the fourth preferred embodiment, which is continued from FIG. 49;

FIG. 51 is a table showing a part of a coding table of motion vectors in the fourth preferred embodiment, which is continued from FIG. 50;

FIG. 52 is a diagram explaining a one-dimensional prediction for motion vectors in the fourth preferred embodiment;

FIG. 53 is a diagram explaining a decoded-value determining method in the case of the syntax of FIG. 40;

FIG. 54 is a diagram explaining a decoded-value determining method in the case of the syntax of FIG. 41;

FIG. 55 is a block diagram of the sixth preferred embodiment of a coding and/or decoding system according to the present invention, which shows a detailed construction of a code-word table preparing part of FIG. 6;

FIG. 56 is a schematic block diagram of the seventh preferred embodiment of a moving-picture coding and/or decoding system according to the present invention;

FIGS. 57A and 57B are diagrams showing examples of syntax in a moving-picture coding system in a moving-picture multiplexing part and a moving-picture multiplex dividing part in the seventh preferred embodiment, respectively;

FIGS. 58A and 58B are diagrams showing examples of syntax in a moving-picture coding system in a moving-picture multiplexing part and a moving-picture multiplex dividing part in the seventh preferred embodiment, respectively;

FIGS. 59A and 59B are block diagrams of a moving-picture multiplexing part and a moving-picture multiplex dividing part of FIG. 55;

FIG. 60 is a block diagram of the eighth preferred embodiment of a source encoder according to the present invention;

FIG. 61 is a block diagram of the eighth preferred embodiments of a source decoder according to the present invention;

FIG. 62 is a schematic diagram of a system incorporating the ninth preferred embodiment of a variable length coding and/or decoding system according to the present invention;

FIG. 63 is a flow chart showing the operation of the tenth preferred embodiment of a variable length encoder according to the present invention;

FIG. 64 is a flow chart showing the operation of the tenth preferred embodiment a forward variable length decoder according to the present invention;

FIG. 65 is a flow chart showing the operation of the tenth preferred embodiment of a backward variable length decoder according to the present invention;

FIG. 66 is an INDEX table of INTRA coefficients;

FIG. 67 is an INDEX table of INTER coefficients;

FIG. 68 is an INDEX table of LASR coefficients;

FIG. 69 is a code-word table in the tenth preferred embodiment;

FIG. 70 is a code-word table in the tenth preferred embodiment;

FIG. 71 is a fixed value code-word table of RUNs in the tenth preferred embodiment;

FIG. 72 is a fixed value code-word table of LEVELs in the tenth preferred embodiment;

FIG. 73 is a diagram illustrating a coding of code words, which are contained in a code-word table;

FIG. 74 is a decoded-value table in the tenth preferred embodiment;

FIG. 75 is a decoded-value table in the tenth preferred embodiment, which is continued from FIG. 74; and

FIG. 76 is a diagram explaining the operation of a decoded-value determining part.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring now to the accompanying drawings, the preferred embodiments of a coding and/or decoding system, according to the present invention, will be described below.

First Preferred Embodiment

FIG. 6 is a block diagram of the first preferred embodiment of a variable length coding and/or decoding system according to the present invention.

As shown in FIG. 6, the variable length coding and/or decoding system in the first preferred embodiment generally comprises a code-word table preparing part 101, a coding part 113, a transmission or storage system 105 and a decoding part 114. First, the functions of the respective parts will be briefly described. The code-word table preparing part 101 prepares a code-word table on the basis of the occurrence probability of source symbols, and transmits code words to a code-word table 102 provided in the coding part 113 and a forward code-word table 111 and a backward code-word table 112, which are provided in the decoding part 114. The coding part 113 encodes the source symbols to a variable length code, and outputs the variable length code as coded data to the transmission or storage system 105. The decoding part 114 decodes the coded data inputted via the transmission or storage system 105 to reproduce the original source symbol.

The detailed constructions and operations of the respective parts in the first preferred embodiments will be described below.

First, in the coding part 113, inputted source symbols are inputted to an encoder 103. The coding part 113 comprises a code-word table 102, the encoder 103 and a synchronization interval setting part 104. The code-word table 102 stores therein source symbols, which have been prepared by the code-word table preparing part 101, and code words of a variable length code so that the source symbols correspond to the code words. The encoder 103 selects code words corresponding to the inputted source symbols from the code words stored in the code-word table 102, to output the selected code words. In the synchronization interval setting part 104, the code words selected by the encoder 103 are grouped every synchronization interval, and stuffing bits capable of being decoded both in forward and backward directions are inserted, to output coded data every synchronization interval. The coded data are transmitted to the decoding part 114 via the transmission or storage system 105.

The decoding part 114 comprises a synchronization interval detecting part 106, a buffer 107, a forward decoder 108, a backward decoder 109, a decoded-value determining part 110, a forward decoding table 111 and a backward decoding table 112. In the decoding part 114, the synchronization interval detecting part 106 detects the synchronization intervals of coded data inputted by the transmission or storage systems 105, and the buffer 107 stores the coded data. The forward decoder 108 starts to decode the coded data stored in the buffer 107 from the prefix of the coded data, and the backward decoder 109 starts to decode the coded data stored in the buffer 107 from the suffix of the coded data.

The forward decoder 108 determines that an error is detected, when a bit pattern, which does not exist in the forward code-word table 111, appears in the coded data and when coded data having a bit number different from the bit number of the buffer 107 is decoded. Similarly, the backward decoder 109 determines that an error is detected, when a bit pattern, which does not exist in the backward code-word table 112, appears in the coded data and when coded data having a bit number different from the bit number of the buffer is decoded.

The decoded-value determining part 110 determines a decoded value on the basis of a decoded result (hereinafter referred to as a “forward decoded result”) obtained by the forward decoder 108 and a decoded result (hereinafter referred to as a “backward decoded result”) obtained by the backward decoder 109, and outputs a final decoded result.

FIG. 7 is a black diagram of the coded-word table preparing part 101. A code selecting part 21 receives information on the occurrence probability of source symbols, and selects a code system having a shortest average code length from selectable code systems to transmit the selected result to a code-word forming part 22. The code-word forming part 22 forms code word of a code selected by the code-word selecting part 21.

The code words formed by the code-word forming part 22 are code words of a variable length code (hereinafter referred to as a “reversible code”), which is formed so that the delimiters in the code can be indicated on the basis of a predetermined weight of code words and which can be decoded both in forward and backward directions. This code is disclosed, e.g., in Japanese Patent Laid-Open No. 7-89772 or 7-260383.

In the first preferred embodiment, in order to increase the degree of freedom for the bit pattern of code words corresponding to a wider probability distribution, the following method for forming code words in the code-word forming part 22 is used.

FIG. 8 shows a first method for forming code words of a reversible code in the code-word forming part 22. First, as shown on the left side of FIG. 8, two binary series, each of which has a constant weight (the weight is the number of “1” in this case) in the order of short code length and which have different weights (the weights are 0 and 1 in this case), are prepared. Then, as shown in the middle of FIG. 8, after “1” s are added to the prefix and suffix of the binary series to reverse the bits of the binary series, the two binary series are synthesized as shown on the right side of FIG. 8.

The code length of this variable length code can be determined by counting the number of symbols at the beginnings of the respective codes. In the example of FIG. 8, when the first is “0”, the delimiter of the code (code length) can be identified if three “0”s in all appear, and when the first is “1”, the delimiter of the code can be identified if two “1”s in all appear. The variable length code shown in FIG. 8 can be decoded both in forward and backward directions since the code words corresponding to all the source symbols A through J are assigned to leaves of a forward decoding tree shown FIG. 9A as well as leaves of a backward decoding tree shown in FIG. 9B.

FIG. 10 shows a second method for forming code words of a reversible code in the code-word forming part 22. First, as shown on the left side of FIG. 10, first and second reversible codes are prepared. Then, as shown in the middle of FIG. 10, a first one code word of the second reversible code is added to each of the suffixes of all the code words of the first reversible code. Then, after all the code words of the second reversible code are added to the suffixes of all the code words of the first reversible code one by one, the code words are rearranged as shown on the right side of FIG. 10 to form a new reversible code. By such a forming method, it is possible to form A×B (27 in this embodiment) new reversible codes, the number of which is obtained by multiplying the number A (A=9 in this embodiment) of the code words of the first reversible code by the number B (B=3 in this embodiment) of the code words of the second reversible code.

When the reversible code is decoded in the forward direction by this forming method, the first reversible code is first decoded, and then, the second reversible code is decoded. When the reversible code is decoded in the backward direction, the second reversible code is first decoded, and then, the first reversible code is decoded. Therefore, the reversible code can be decoded both in the forward and backward directions.

Furthermore, in this embodiment, while the code words of the second reversible code have been added to the suffix of the code words of the first reversible code, the second reversible code may be added to the prefix of the first reversible code. Alternatively, fixed length codes may be added to both the suffix and prefix of the first reversible code. In addition, in this embodiment, while the first reversible code has been different from the second reversible code, both may be the same. Moreover, in this preferred embodiment, while variable length codes have been used as both of the first and second reversible codes, any one of the first and second reversible codes may be changed to a fixed length code.

FIG. 11 shows a third method for forming a reversible code in the code-word forming part 21. First, as shown on the left side of FIG. 11, variable-length reversible codes and fixed-length reversible codes are prepared. Then, as shown on the right side of FIG. 11, the fixed-length reversible codes are added immediately after the respective bits of the code words of the reversible codes. When K-bit fixed-length reversible codes are used by this forming method, H-bit code words can be changed to (K+1)H-bit code words to increase the number of code words by 2KH. In this embodiment, while the fixed length codes have been added immediately after the respective bits of the code words of the reversible codes, fixed length codes may be added immediately before the respective bits, or fixed length codes may be added both immediately before and after the respective bits.

Referring to FIGS. 12A and 12B, examples of methods for setting synchronization intervals of coded data in the synchronization interval setting part 104 will be described below.

FIG. 12A shows a method for setting synchronization intervals by inserting synchronization patterns. In this case, the synchronization interval detecting part 106 can detect the synchronization intervals by detecting the first and last synchronization patterns of coded data. In order to set positions, at which synchronization patterns can be inserted, at predetermined intervals (every M-bit unit in this case), 1-bit to M-bit stuffing codes are inserted into the suffixes of the coded data.

FIG. 12B shows a method for describing the coding amount of the synchronization interval on the prefix of the coded data, i.e., a method for inserting a pointer indicative of the end position of the synchronization interval. In this case, the synchronization interval detecting part 106 can detect the synchronization interval by decoding the description of the coding amount of the synchronization interval at the prefix of the coded data. Since the unit of description of the coding amount is a M-bit unit, 1-bit to M-bit stuffing codes are inserted into the suffix of the coded data.

The stuffing codes used for the methods of FIGS. 12A and 12B can be decoded at least in the backward direction. FIG. 13 shows an example of such a stuffing code. This stuffing code can be decoded both in the forward and backward directions. This stuffing code is a variable length code, the delimiter of which can be identified if “1” appears in the case of 1 bit and if “0”s appear twice in the case of other bits, and which can be decoded both in the forward and backward directions. This stuffing code can be also decoded from the end of the synchronization interval in the backward direction, and the bit number of the coded data can be calculated. The calculated result of the bit number of the coded data is used for an error detection, which will be described later.

While the stuffing code has been inserted into the suffix of the coded data in this embodiment, the stuffing code may be inserted into the prefix or the internal portion of the coded data. The stuffing code may be inserted into a portion in the synchronization interval at any positions if there is no problem of syntax. Alternatively, the stuffing code may be a code capable of being decoded only in the backward direction as shown in FIG. 14. The delimiter of this code can be identified if “0” appears when being decoded in the backward direction.

Referring to FIGS. 15A through 15D, a method for determining a decoded value in the decoded-value determining part 110 will be described below.

As shown in FIG. 15A, when the ways to the positions of the decoded word (error detected positions), at which errors are detected, in the forward and backward decoded results, do not overlap with each other, only the decoded results, in which the errors are not detected, are used for decoded values, and the decoded results at the two error detected positions are abandoned. As shown in FIG. 15B, when the ways to the error detected positions in the forward and backward decoded results overlaps with each other, the forward decoded results are used for decoded values before the error detected position in the forward decoded results, and the backward decoded results are used for decoded values after the error detected position in the forward decoded results. Alternatively, the backward decoded results may be preferentially used for decoded values before the error detected position in the backward decoded result, and the forward decoded results may be used for decoded values after the error detected position in the backward decoded result.

As shown in FIG. 15C, when an error is detected in only one of the forward and backward decoded results (an error is detected only in the forward decoded result in the shown embodiment), the decoded values in the forward decoded result are used before the error detected position, and the decoded values in the backward decoded result are used after the error detected position. As shown in FIG. 15D, when errors are detected in the same code word both in the forward and backward decoded results, the decoded value for the code word at the error detected position is abandoned, and the decoded values in the backward decoded result are used for the code words after the error detected position. When the error determination is carried out in the forward decoder 108 and the backward decoder 109, if a bit pattern, which does not exist as a code word, appears, the position of the bit pattern is regarded as the decoded position. When no error is detected in the above determining method and when the decoded bit number is not coincident with the bit number of the coded data in the synchronization interval, the first position in decoding is regarded as the error detected position.

In this first preferred embodiment, while one example of a decoded-value determining method using four patterns of error detected positions has been described, the decoded-value determining part may use any methods, if the forward or backward decoded result presumed to be correct is used and a portion, which has not been detected both in the decoded results, is abandoned, when errors are detected in both or any one of the forward and backward detected results.

Second Preferred Embodiment

As the second preferred embodiment of the present invention, an applied example of a variable length coding and/or decoding system according to the present invention will be described below.

FIG. 16 is a block diagram showing the concept of a moving picture coding and/or decoding system, which incorporates the second preferred embodiment of a variable length coding and/or decoding system according to the present invention. First, in a moving picture encoder 709, the variable length coding, multiplexing and so forth of data coded by a source encoder 702 are carried out by means of a moving picture multiplexer 703. Then, the resulting data are smoothed by means of a transmission buffer 704 to be transmitted to a transmission or storage system 705 as coded data. A coding control part 701 controls the source encoder 702 and the moving picture multiplexer 703 in view of the buffer capacity of the transmission buffer 704.

On the other hard, in a moving picture 710, the coded data transmitted tom the transmission or storage system 705 are stored in a receiving buffer 706. Then, the multiplexing separation and variable length decoding of the coded data are carried out by means of a moving picture multiplexing separator 707 to be transmitted to a source decoder 708, in which the moving picture information is finally decoded. To the moving picture multiplexer 703 and the moving picture multiplexing separator 707, the first preferred embodiment of a variable length coding and/or decoding system according to the present invention is applied.

FIGS. 17A through 17C shows syntax of a moving picture coding system in the moving picture multiplexer 703 and the moving picture multiplexing separator 707 in the second preferred embodiment. The mode information, motion vector information and INTRA DC (DC components of DCT coefficients in intraframe coding) information of macro blocks are applied to an upper layer, and DCT coefficient information except for the INTRA DC is applied to a lower layer. Reversible codes are applied to the lower layer.

FIGS. 18A and 18B are block diagrams illustrating the moving picture multiplexer 703 and the moving picture multiplexing separator 707 in the second preferred embodiment. In the moving picture multiplexer 703 shown in FIG. 18A, out of the data coded by the source encoder 702 of FIG. 16, the mode information, motion vector information and INTRA DC information of macro blocks are applied to an upper layer, and the usual variable length coding is carried out by means of an upper-layer variable length encoder 901 to be transmitted to a multiplexer 903. Out of the data coded by the source encoder 702, DCT coefficients other than the INTRA DC are coded by means of reversible codes in a lower-layer variable length encoder 902 to be transmitted to the multiplexer 903. In the multiplexer 903, the coded data of the upper and lower layers are multiplexed to be transmitted to a transmission buffer 704.

On the other hand, in the moving picture multiplexing separator decoder 707 shown in FIG. 18B, the coded data of the upper and lower layers are separated by means of a multiplexing separating part 904 to be variable-length decoded by means of an upper-layer variable length decoder 905 and a lower-layer variable length decoder 906, respectively.

FIGS. 19 through 21 and 22 through 23 show examples of code-word tables used for the lower-layer variable length encoder 902. The codes stored in these code tables are obtained bad adding 2-bit fixed-length codes to the suffix of each of the codes prepared by the first forming method for the code words of the reversible code in the code-word forming part 22.

In the source encoder 702, the interior of blocks is scanned every block of 8×8 DCT coefficients after quantization to derive LASTs (0: non-zero coefficients, each of which is not the last of the block, 1: non-zero coefficients of the last of the block), RUNs (the numbers of zero runs before the non-zero coefficients) and LEVELs (quantized values of the coefficients), which are transmitted to the moving picture multiplexing part 703.

The lower-layer variable length encoder 902 in the moving picture multiplexing part 703 has a code-word table of non-LAST coefficients shown in FIGS. 19 through 21, wherein the code words of reversible codes (VLC_CODE) correspond to the non-LAST coefficients, RUNs and LEVELs of the INTRA (intraframe coding) and INTER (interframe coding), and a code-word table of LAST coefficients shown in FIGS. 22 and 23, wherein the code words of the reversible codes (VLC_CODE) correspond to the LAST coefficients, RUNs and LEVELs of the INTRA and INTER.

On the basis of the mode information, one of the code-word tables of the non-LAST coefficients and LAST coefficients of the INTRA is selected when the INTRA is carried out, and one of the code-word tables of the non-LAST coefficient and LAST coefficients of the INTER is selected when the INTER is carried out, so that coding is carried out. The last bit “s” of the code word denotes the sign of the LEVEL. When the “s” is “0”, the sign of the LEVEL is positive, and when the “s” is “1”, the sign of the LEVEL is negative.

With respect to coefficients, which do not exist in these code-word tables, 1 bit indicative of the LAST coefficient, the RUN and the absolute value of the LEVEL are fixed-length coded as shown in FIG. 25. In addition, the “00001” of two escape codes is added to the prefix of the fixed length code, and an escape code is also added to the suffix thereof. FIG. 24 shows a code-word table of escape codes. The last bit “s” of the VLC_CODE used as an ESCAPE code denotes the sign of the LEVEL. When the “s” is “0”, the LEVEL is positive, and when the “s” is “1”, the LEVEL is negative.

FIG. 26 shows the case that the zero run is maximum when this code-word table is used. Usually, a bit pattern, wherein “1” is added after zero runs continue, is selected as a synchronization pattern. For example, in the case of ITU-T H.263, a bit pattern, wherein “1” is added after 16 “0”s, is selected as a synchronization pattern. In the variable-length coding of the DCT coefficients, the zero run is maximum when 15 “0”s continue in a case where the LEVEL is +64 in the coefficient using an escape code and the next code also uses an escape code. Therefore, if a bit pattern, in which 16 “0”s continue, is used as a synchronization pattern, there is no possibility that a pseudo synchronization pattern may be produced.

The decoded-value determining part 110 determines a decoded value on the basis of the decoded result (hereinafter referred to as a “forward decoded result”) obtained by the forward decoder 108 and the decoded result (hereinafter referred to as a “backward decoded result”) obtained by the backward decoder 109 to output a final decoded result. In the error determinations in the forward decoder 108 and the backward decoder 109, when a bit pattern, which does not exist as a code word, appears and when an error is detected by a check bit or the like, the position of the bit pattern or the error is used as the detected position, and when no error is not detected by the above determining method and when the decoded bit number is not coincident with the bit number of the coded data in the synchronization interval, the first position of decoding is used as the error detected position.

FIG. 27 shows a method for determining a decoded value in the lower layer. First, as shown in FIG. 27(a), when the ways to the positions (the error detected positions) of macro blocks (MB), at which errors are detected in the forward and backward decoded results, do not overlap with each other, only the decoded results of the macro blocks, in which no error is not detected, are used for decoded values, and the decoded results at two error detected positions are not used for decoded values. In addition, the decoded results of the upper layer are rewritten on the basis of the decoded results of the mode information of the upper layer so that the INTRA macro blocks (intraframe coded macro blocks) are displayed using the last frame and the INTER macro blocks (interframe coded macro blocks) are displayed only by the motion compensation using the last frame.

As shown in FIG. 27(b), when the ways to error detected positions in the forward and backward decoded results overlap with each other, the forward decoded results before a macro block, in which an error is detected as a result of the forward decoding, are used for decoded values, and the backward decoded results are used for decoded values after the macro block. Alternatively, the backward decoded results may be preferentially used for decoded results after a macro block, in which an error is detected as a result of the backward decoding, and the forward decoded results may be used for decoded values before the macro block.

As shown in FIG. 27(c), when an error is detected in only one of the forward and backward decoded results (an error is detected only in the forward decoded result in the shown embodiment), the backward decoded results are used for decoded values with respect to the macro blocks after the error detected position.

As shown in FIG. 27(d), when errors are detected at the same macro block both in the forward and backward decoded results, the decoded values of the macro block at the error detected position are abandoned so as not to be used as decoded values. In addition, the decoded results of the upper layer are rewritten on the basis of the decoded results of the mode information of the upper layer so that the INTRA macro blocks are displayed using the last frame and the INTER macro blocks are displayed only by the motion compensation using the last frame. The backward decoded results are used for decoded values with respect to the macro block after the error detected position.

While the decoded values has been determined every macro block in the decoded-value determining method of FIG. 27, the decoded values may be determined every block or code word. In the second preferred embodiment, while the present invention has been applied to the variable-length coding of the DCT coefficients, the invention may be applied to other source symbols when the variable-length coding is carried out.

Third Preferred Embodiment

Referring to FIG. 28, the third preferred embodiment of a variable length coding and/or decoding system, according to the present invention, will be described below.

In this third preferred embodiment, the variable length coding and/or decoding system generally comprises a code-word table preparing part 101, a coding part 113, a transmission or storage system 105 and a decoding part 121. First, the functions of the respective parts will be briefly described. The code-word table preparing part 101 prepares a code-word table on the basis of the occurrence probability of source symbols, and transmits code words to a code-word table 102 in the coding part 113 and to forward and backward code-word tables 111 and 112 in the decoding part 121. The coding part 113 encodes the source symbol to a variable length code, and outputs the variable length code to the transmission or storage system 105 as coded data. The decoding part 121 decodes the coded data inputted via the transmission or storage system 105 to reproduce the original source symbol.

The detailed constructions and operations of the respective parts in the third preferred embodiment will be described below.

The construction and operation of the coding part 113 are the same as those in the first preferred embodiment shown in FIG. 6. That is, in the coding part 113, inputted source symbols are inputted to an encoder 103. The code-word table 102 stores therein source symbols prepared by the code-word table preparing part 101 and code words of variable length codes so that the source symbols correspond to the code words. The encoder 103 selects code words corresponding to the inputted source symbols from the code words stored in the code-word table 102. In a synchronization interval setting part 104, the code words selected by the encoder 103 are grouped every synchronization interval, and stuffing bits capable of being decoded both in forward and backward directions are inserted into the code words to output coded data every synchronization interval. The coded data are transmitted to the decoding part 121 via the transmission or storage system 105.

The decoding part 121 comprises a synchronization interval detecting part 106, a buffer 107, a coded data switch 122, a decoder 124, a code-word table switch 125, a decoded-value determining part 110, a forward decoding table 111 and a backward decoding table 112. The coded data switch 122 and the code-word table switch 125 are controlled by the decoder 124 to be switched. In the decoding part 121, while the synchronization interval detecting part 106 inspects the synchronization interval of the coded data inputted by the transmission or storage systems 105, the coded data are inputted to the decoder 124. At this time, the coded data are also stored in the buffer 107. The decoder 124 starts to decode the inputted coded data (hereinafter referred to as “forward decoding”). The decoder 124 determines that an error is detected, when a bit pattern, which does not exist in the forward code-word table 111, appears and when coded data having a bit number different from the bit number of the buffer 107 is decoded.

When it is determined that an error has been detected, the decoder 124 switches the code-word table in the code-word table switch 123 from the forward code-word table 111 to the backward code-word table 112. At this time, the input to the decoder 124 is switched to the buffer 107 by means of the coded data switch 122. When the synchronization interval detecting part 106 detects the next synchronization, the stored coded data are read out of the buffer 107 from the suffix to be outputted to the decoder 124. The decoder 124 starts to decode the inputted coded data (hereinafter referred to as “backward decoding”). Similar to the forward decoding, the decoder 124 determines that an error is detected, when a bit pattern, which does not exist in the backward code-word table 112, appears in the coded data or when coded data having a bit number different from the bit number of the buffer 107 are decoded. The decoded-value determining part 110 determines decoded values on the basis of a decoded result (hereinafter referred to as a “forward decoded results”) obtained by the forward decoding and a decoded result (hereinafter referred to as a “backward decoded results”) obtained by the backward decoding to output a final decoded result.

In the third preferred embodiment, the coded-word table preparing part 101 is basically the same as that in the first preferred embodiment. As shown in FIG. 7, the code-word table preparing part 101 inputs information on the occurrence probability of source symbols, and comprises a code-word selecting part 21 for selecting a code system having a least average code length from selectable code systems, and a code-word forming part 22 for forming code words of a code selected by the code-word selecting part 21. In this preferred embodiment, the following method for forming code words in the code-word forming part 22 is used in order to increase the degree of freedom for a bit pattern of code words so as to correspond to a wider probability distribution.

FIG. 29 shows a first method for forming code words of a reversible code in the code-word forming part 22. First, as shown on the left side of FIG. 29, a first reversible code is prepared. Then, as shown in the middle of FIG. 29, fixed length codes of (code length−1) bits surrounded by the broken line are prepared for the respective code words of the first reversible code, and as shown on the right side of FIG. 29, the code words of the fixed length codes are inserted between the respective bits of the code words of the first reversible code 1 bit by 1 bit so as to be surrounded by the broken line. It can be seen that the variable length codes of FIG. 29 can be decoded both in the forward and backward directions by decoding the fixed length codes every 1 bit while decoding the first reversible code. In the embodiment of FIG. 29, while the code words of the fixed length codes have been inserted between the respective bits of the code words of the first reversible code 1 bit by 1 bit, fixed length codes of (code length−1)×n bits may be prepared for the respective code words of the first reversible code, and the code words of the fixed length codes may be added between the respective bits of the code words of the first reversible code n bits by n bits.

FIG. 30 shows a second method for forming code words of a reversible code in the code-word forming part 22. As shown on the left side of FIG. 30, a first reversible code is prepared. Then, as shown on the upper side of FIG. 30 so as to be surrounded by the broken line, a second reversible code is prepared, and as shown on the right side of FIG. 30, the second reversible code is inserted between the respective bits of the code words of the first reversible code so as to be surrounded by the broken line. It can be seen that the variable length codes of FIG. 30 can be decoded both in the forward and backward directions by decoding the second reversible code 1 bit by 1 bit while decoding the first reversible code. In the embodiment of FIG. 30, while the first and second reversible codes have been the same, these codes may be different.

In the third preferred embodiment, as shown in FIG. 31, a bidirectional code-word table 51 may be used as a common table in place of the forward code-word table 111 and the backward code-word table 112 shown in FIG. 28. In this case, an identification signal 53 indicative of the discrimination between the forward coding and the backward coding is inputted from the decoder 124 of FIG. 28, and an address converter 52 is operated by the identification signal 53 to produce an address for reading code words out of the bidirectional code-word table 51. Then, the code value corresponding to this address is read out of the bidirectional code-word table 51.

In the third preferred embodiment, as shown in FIG. 32, the decoder 124 has an error detection function. An error detecting part 62 connected to a decoder 61 monitors the inside state of the decoder 61, and outputs an error detection signal when it is abnormal. For example, the abnormal inside states include the following states:

(1) when a coded data, which does not exist in the code-word table, is received;

(2) when the length of the coded data is not coincident with the length of the code actually decoded by the decoder 61;

(3) when the decoded value is inadequate although the decoded value can be derived since it exists in the code-word table, specifically, (3-1) when the decoded value is beyond the range of existence, (3-2) when the number of data exceeds the upper limit, and (3-3) when a decoded value, which does not match with the previously decoded value, is outputted; and

(4) when an error has been detected by an error detection code or the like.

Referring to FIG. 33, a decoding method in the third preferred embodiment will be described below.

In the preceding preferred embodiments, as shown in FIG. 33(a), the forward and backward decoding processes in the decoder 124 have been simultaneously carried out until errors are detected in the respective processes, to derive decoded values. The third preferred embodiment should not be limited thereto, but decoding may be carried out by the methods shown in FIGS. 33(b), 33(c) and 33(d). In FIGS. 33(b), 33(c) and 33(d), X denotes error detected points, the arrow to the right denotes the forward decoding process, and the arrow to the left denotes the backward decoding process.

In the method shown in FIG. 33(b), the forward decoding process is carried out, and when an error is detected, the forward decoding process is stopped and the backward decoding process is carried out in the backward direction from the suffix of the coded data in the synchronization interval until an error is detected. In the method shown in FIG. 33(c), when an error is detected in the forward decoding process, the forward decoding process is resumed after n bits from the error detected position. This process is repeated until all the coded data in the present synchronization interval are processed. At the last of the forward decoding process, when the number of the coded data in the synchronization interval is not coincident with the number of data decoded by the decoding process, it is determined that an error is detected, and the backward decoding process is carried out from the suffix of the coded data until an error is detected. In the method shown in FIG. 33(d), when an error is detected in the forward decoding process, the backward decoding process is carried out by n bits in the backward direction from n bits after the error detected position. Thereafter, the forward decoding process is carried out after n bits from the error detected position, i.e., the forward decoding process is carried out from a position, at which the backward decoding process has been started. This process is repeated until all the coded data in the present synchronization interval are processed. Finally, if the number of the coded data in the synchronization interval is not coincident with the number of data decoded by the decoding process, it is determined that an error is detected, and the backward decoding process is carried out from the suffix of the coded data until an error is detected.

Referring to FIG. 34, a method for determining decoded values in the decoded-value determining part 111 in the third preferred embodiment will be described below. The decoded values finally utilized in the decoded-value determining part 111 can be selected by the following methods.

In the decoded-value determining method shown in FIG. 34(a), after an error is detected, decoding is not carried out. That is, since there is a possibility that erroneous decoding may be carried out after an error is detected, the decoded values, which may cause erroneous decoding, are not utilized, and only the decoded values before the error detected position are utilized.

In the decoded-value determining method shown in FIG. 34(b), even if an error is detected, decoding is continued to utilize all the usable decoded values. Variable length codes include a code, in which synchronization can be automatically recovered if the decoding process is continuously carried out even if the synchronization is not broken. This is called “self-synchronization-recovery. In the case of a code word having a high self-synchronization-recovery capability, it is possible to obtain a greater amount of correct decoded values by continuing the decoding process as shown in FIG. 34(b) without stopping the decoding process as shown in FIG. 34(a) after the error is detected. However, in this case, there is a possibility that the decoded values may include erroneously decoded values. In the system for allowing such a possibility of erroneous decoding, the decoded-value determining method of FIG. 34(b) may be used.

Fourth Preferred Embodiment

Referring to FIG. 35, the fourth preferred embodiment of a variable length coding and/or decoding system, according to the present invention, will be described below.

In the fourth preferred embodiment, the variable length coding and/or decoding system generally comprises a code-word table preparing part 201, a coding part 213, a transmission or storage system 205 and a decoding part 214. First, the functions of the respective parts will be briefly described.

The code-word table preparing part 201 prepares a code-word table on the basis of the occurrence probability of source symbols, to transmit code words to a code-word table in the coding part 213 and to forward and backward code-word tables in the decoding part 214.

The coding part 213 layers source symbols provided as input data, and encodes the input data every layer to variable length codes. Then, the coding part 213 multiplexes the variable length codes to output the multiplexed codes to the transmission or storage system 205. The decoding part 214 multiplexing-separates the coded data inputted via the transmission or storage system 205 to variable-length decode the resulting data every layer to synthesize decoded results every layer to reproduce the original source symbols to output reproduced data.

The detailed constructions and operations of the respective parts in the fourth preferred embodiment will be described below.

In the coding part 213, the source symbols being input data are divided, by means of a data layering part 202, into layers 1 through n (n is a natural number being not less than 2) in accordance with importance. The divided source symbols in the respective layers i (i=1, 2, . . . n) are inputted to variable length coding parts 203-i prepared every layer i to be coded. The coded data of the respective layers i obtained by the variable length coding parts 203-i are multiplexed by means of a multiplexing part 204 to be transmitted to the decoding part 214 via the transmission or storage system 205.

In the decoding part 214, the coded data inputted by the transmission or storage system 205 are divided into coded data of the respective layers i by means of a multiplexing separating part 206. The divided coded data of the respective layers are inputted to variable length decoding parts 207-i prepared every layers i to be decoded. The decoded results of the respective layers i obtained by the variable length decoding parts 207-i are synthesized by means of a data synthesizing part 208 to be outputted as reproduced data.

The construction of the code-word table preparing part 201 is the same as that of the code-word table preparing part 101 in the first preferred embodiment shown in FIG. 7. The code-word table preparing part 201 selects a code system having a shortest average code length from selectable code systems on the basis of information on the occurrence probability of source symbols, to form code words of the selected code. The code words are variable length codes (reversible codes), which are formed so that the delimiters between codes can be identified by a predetermined weight of code words and which can be decoded both in forward and backward directions.

The construction of each of the variable length coding parts 203-i of the respective layers i of FIG. 35 is shown in FIG. 36. Similar to the coding part 113 shown in FIG. 6, each of the variable length coding parts 203-i comprises a code-word table 102, an encoder 103 and a synchronization interval setting part 104. That is, the source symbols inputted from the data layering part 202 of FIG. 35 are inputted to the encoder 103. The code-word table 102 stores therein source symbols previously prepared by the code-word table preparing part of FIG. 35 and code words of variable length codes so that the source symbols correspond thereto.

The encoder 103 selects code words corresponding to the source symbols inputted by the data layering part 202, from the code words stored in the code-word table 102 to output the selected code words. The synchronization interval setting part 104 groups the code words selected by the encoder 103 every synchronization interval, and inserts stuffing codes, which can be decoded both in forward and backward directions, into the grouped code words if necessary, to output coded data every synchronization interval. The coded data are transmitted to the multiplexing part 204 of FIG. 35.

On the other hand, the construction of each of the variable length decoding parts 207-i of the respective layers i of FIG. 35 is shown in FIG. 37. Similar to the decoding part 114 shown in FIG. 6, each of the variable length decoding parts 207-i comprises a synchronization interval detecting part 106, a buffer 107, a forward decoder 108, a backward decoder 109, a decoded-value determining part 110, a forward decoding table 111 and a backward decoding table 112. That is, in the variable length decoding part 207-i, the synchronization intervals of the coded data inputted from the transmission or storage system 205 by the synchronization interval detecting part 106 and the coded data are stored in the buffer 107. The forward decoder 108 starts to decode the coded data stored in the buffer 107 from the prefix of the coded data. The backward decoder 109 starts to decode the coded data stored in the buffer 107 from the suffix of the coded data.

The forward decoder 108 determines that an error is detected, when a bit pattern, which does not exist in the forward code-word table 111, appears in the coded data or when the coded data having a bit number different from the bit number of the buffer 107 is decoded. Similarly, the backward decoder 109 determines that an error is detected, when a bit pattern, which does not exist in the backward code-word table 112, appears in the coded data or when the coded data having a bit number different from the bit number of the buffer 107 is decoded. The decoded-value determining part 110 determines decoded values on the basis of a decoded result (a forward decoded result) obtained by the forward decoder 108 and a decoded result (a backward decoded result) obtained by the backward decoder 109, to output a final decoded result. The decoded results of the respective layers i are transmitted to the data synthesizing part 208.

FIGS. 38A through 38C show examples of the data hierarchization in the data layering part 202 and the multiplexing in the multiplexing part 204. If there are input data (a source symbol string) of syntax, which can be divided into n layers as shown in FIG. 38A, the data layering part 202 changes the syntax to carry out the data hierarchization so that the input data are repeated every layer i as shown in FIG. 38B, and transmits the source symbols to the variable length coding part 203-i every layer i. In the multiplexing part 204, as shown in FIG. 38C, the source symbols are variable-length coded by the variable length coding part 203-i every layer i, and the coded data, in which the synchronization intervals are set by adding the synchronization pattern i, are multiplexed to be outputted.

FIG. 39 shows an example of a method for determining decoded values in the decoded-value determining part 110 of FIG. 37. In the variable length decoding part 207-i of the respective layer i, the bidirectional decoding is carried out. If there is an error in the decoded data inputted to the variable length decoding part of a certain layer, the error affects the decoded values of upper and lower layers than the certain layer. Therefore, the decoded-value determining part 110 in the variable length decoding part 207-i of the respective layer i exchanges information to determine the final decoded value.

In the embodiment of FIG. 39, if there is an undecodable portion in the upper layer due to an error, an undecodable portion is produced in the decoded data of the lower layer relating thereto. In addition, if there is an undecodable portion in the coded data of the lower layer due to an error, the decoded values of the coded data of the upper layer corresponding thereto are changed. FIG. 39 merely shows one example of a decoded-value determining method. Therefore, it is possible to utilize any methods, wherein the decoded-value determining part 110 in the variable length decoding part 207-i of each of the layers i uses a decoded result, which is presumed to be correct, of the forward and backward decoded results when an error is detected in at least one of the forward and backward decoded results using the decoded results of the upper and lower layers, and wherein the decoded result of a portion, which could not have been decoded both in the forward and backward decoding processes, is abandoned. In the fourth preferred embodiment, while the reversible codes have been used both in the forward and backward directions in all the layers, reversible codes may be used only in a part of layers.

Fifth Preferred Embodiment

The fifth preferred embodiment, wherein the variable length coding and/or decoding system in the fourth preferred embodiment is applied to the moving picture multiplexing part 703 and the moving picture multiplexing separating part 707 of the moving picture coding and/or decoding system shown in FIG. 16, will be described below. In this case, the basic construction of the moving picture coding and/or decoding system is the same as that in the second preferred embodiment, except that the variable length coding and decoding processes in the moving picture multiplexing part 703 and the moving picture multiplexing separating part 707 are carried out every layer.

FIGS. 40A, 40B, 41A, 41B, 42A, 42B, 43A and 43B show various examples of syntax of a moving picture coding system in the moving picture multiplexing part 703 in the fifth preferred embodiment. First, the syntax shown in FIGS. 40A and 40B will be described. In this syntax, inputted source symbols being coded data are divided into two layers, i.e., an upper layer and a lower layer, and synchronization intervals are set for the respective layers using synchronization patterns RM and MM. Symbol ST at the suffix of the syntax of the lower layer is a stuffing code capable of being decoded in the backward direction shown in FIG. 14.

As shown in FIG. 40A, the upper layer includes a header information and a mode information, which is arranged on the side of the prefix and which includes coding modes for each of macro blocks, information on the need for coding the respective blocks, and values of INTRA DC. These informations are described by variable length codes capable of being decoded in the usual forward direction. In addition, motion vector informations are variable-length coded to reversible codes by means of coding tables shown in FIGS. 44 through 51 to be arranged after the header and mode informations. In the coding tables shown in FIGS. 44 through 51, “VECTOR DIFFERENCES” denotes predicted values (differential values) of motion vectors, “BIT NUMBER” denotes code lengths of variable length codes, and “VLC CODE” denotes variable length codes.

As shown in FIG. 52, motion vectors are obtained by one-dimensional predictions, and predicted values are represented by differential values. The predicting directions of the motion vector is shown by arrows in FIG. 52. As shown in FIG. 52, a macro block (shown by a greater rectangle in FIG. 52) has one motion vector or four motion vectors, each of which exists in each of luminance blocks (shown by smaller rectangles in FIG. 52).

The one-dimensional prediction is carried out with respect to these blocks, and predicted values are described by variable length codes in accordance with the coding tables shown in FIGS. 44 through 51. This corresponds to the motion vector information at the end of FIG. 40A. On the other hand, as shown in FIG. 40B, the lower layer has DCT coefficient information other than the INTRA DC. For example, the lower layer is described by reversible codes, which are shown in FIGS. 19 through 25 or disclosed in Japanese Patent Application No. 7-260383.

The syntax shown in FIGS. 41A and 41B will be described. In this syntax, as shown in FIG. 41A, a header information and a mode information 1 indicative of the number of motion vectors for each macro coding are arranged on the side of the prefix of the upper layer to be described by variable length codes capable of being decoded in the usual forward direction, and the variable length codes of the motion vectors are described after the header information and the mode information. The variable length codes of the motion vector information are the same as those of the syntax of FIG. 40A. As shown in FIG. 41B, a mode information 2 indicative of the presence of DCT coefficients in the respective blocks and the INTRA DC are arranged on the side of the prefix of the lower layer to be described by variable length codes capable of being decoded in the usual forward direction, and a DCT coefficient information other than the INTRA DC is described by reversible codes after the DCT coefficient information similar to the syntax of FIG. 40B The syntax shown in FIGS. 42A and 42B will be described. In this syntax, only variable length codes capable of being decoded in the forward direction are used for the upper layer. That is, as shown in FIG. 42A, in the upper layer, a header information, a mode information and a motion vector information are described by variable length codes capable of being decoded in the forward direction. In the lower layer, as shown in FIG. 42B, a DCT coefficient information is described by reversible codes similar to the syntax of FIG. 40B.

The syntax shown in FIGS. 43A and 43B also uses, in the upper layer, only variable length codes capable of being decoded in the forward direction. That is, as shown in FIG. 43A, in the upper layer, a header information, a mode information 1 indicative of the number of motion vectors for each macro coding, and a motion vector information are described by variable length codes capable of being decoded in the forward direction. As shown in FIG. 43B, in the lower layer, a mode information 2 indicative of the presence of DCT coefficient of each block, and an INTRA DC are arranged on the side of the prefix to be described by variable length codes capable of being decoded in the usual forward direction, and in the rear thereof, a DCT coefficient information other than the INTRA DC is described by reversible codes similar to the syntax of FIG. 41B.

In the fifth preferred embodiment, although the basic constructions of the moving picture multiplexing part 703 and the moving picture multiplexing separating part 707 are the same as those of FIGS. 18A and 18B, the constructions of the upper-layer variable length encoder 901, the lower-layer variable length encoder 903, the upper-layer variable length decoder 905 and the lower-layer variable length decoder 906 are different from those in the second preferred embodiment. That is, out of data coded by the source encoder 702, the upper layer data indicated by, e.g., the syntax of FIGS. 40A or 41A, are variable-length coded by means of the upper-layer variable length encoder 901 to be transmitted to the multiplexing part 903. In addition, out of data coded by the source encoder 702, the lower layer data indicated by the syntax of FIG. 40B or 41B are variable-length coded by means of the lower-layer variable length encoder 903 to be transmitted to the multiplexing part 903. In the multiplexing part 903, the coded data in the upper and lower layers are multiplexed to be transmitted to the transmission buffer 704.

In the fifth preferred embodiment, the decoded-value determining part 110 (shown in FIG. 37) in the upper-layer variable length decoder 905 and the lower-layer variable length decoder 906 determines decoded values on the basis of the forward decoded result obtained by the forward decoder 108, to output a final decoded result. In the error detection in the forward decoder 108 and the backward decoder 109 in the respective layers, when a bit pattern, which does not exist as code words, appears or when an error is detected is by a check bit or the like, the position of the bit pattern or the error is regarded as a detected position. When no error is detected by the above described determining method and when the number of decoded bits is not coincident with the bit number of coded data in the synchronization interval, the first decoding position is regarded as an error detected position.

In the fifth preferred embodiment, a decoded-value determining method will be described below.

FIG. 53 shows a decoded-value determining method when the syntax of the moving picture coding system in the moving picture multiplexing part 703 is the syntax shown in FIGS. 40A and 40B. Since the syntax of FIGS. 40A and 40B uses reversible codes for the motion vector information of the upper layer and the DCT coefficient information of the lower layer, the bidirectional decoding can be carried out both in the upper and lower layers.

In the upper layer, the header information and the mode information are first decoded. When the header information and/or the mode information can not be completely decoded due to an error, all the decoded values of the macro blocks of a synchronization interval, in which the error occurs, are regarded as “Not Coded”, and the last screen is directly displayed. If all the header information and the mode information can be decoded, the bidirectional decoding of the motion vector information is then carried out. A portion of the motion vector information, which can not decoded, is regarded as “Not Coded”. In the lower layer, the DCT coefficient information of the lower layer is used for only macro blocks, which have been decoded to the motion vector. The macro blocks, in which the DCT coefficient information has been abandoned due to the error, are regarded as “Not Coded”.

FIG. 54 shows a decoded-value determining method when the syntax of the moving picture coding system in the moving picture multiplexing part 703 is the syntax shown in FIG. 41. According to the syntax of FIG. 41, in the upper layer, the header information and the mode information 1 are first decoded. If the header information and/or the mode information 1 can not be completely decoded due to an error, all the decoded value of macro blocks in a synchronization interval, in which the error has occurred, are regarded as “Not Coded”, and the last screen is directly displayed. If all the header information and the mode information 1 can be decoded, the bidirectional decoding of the motion vector information is then carried out. A portion of the motion vector information, which can not be decoded, is regarded as “Not Coded”. In the lower layer, the DCT coefficient information of the lower layer is used for only macro blocks, which have been decoded to the motion vector. The macro blocks, in which the DCT coefficient information has been abandoned due to the error, are regarded as “Not Coded”.

While the decoded values have been determined every macro blocks in the decoded-value determining methods shown in FIGS. 53 and 54, the decoded values may be determined every block or code word. In the fifth preferred embodiment, while the present invention has been applied to the variable length codes of the motion vector information and the DCT coefficient information, the invention may be applied to other source symbols for variable length coding.

Sixth Preferred Embodiment

The sixth preferred embodiment of a variable length coding and/or decoding system, according to the present invention, will be described below. Since the basis constructions in the sixth preferred embodiment are the same as those in the first preferred embodiment shown in the block diagram of FIG. 6, the sixth preferred embodiment will be described referring to FIG. 6.

In a coding part 113, inputted source symbols are inputted to an encoder 103. A code-word table 102 stores therein source symbols previously prepared by a code-word table preparing part 101 and code words of variable length codes so that the source symbols correspond to the code words. The encoder 103 selects code words corresponding to the inputted source symbols from the code words stored in the code-word table 102. A synchronization interval setting part 104 outputs the code words selected by the encoder 103, as coded data every synchronization interval. The coded data are transmitted to a decoding part 114 via a transmission or storage system 105.

In the decoding part 114, a synchronization interval detecting part 106 detects the synchronization interval of the coded data inputted by the transmission or storage systems 105, and a buffer 107 stores therein the coded data. A forward decoder 108 starts to decode the coded data stored in the buffer 107 from the prefix of, the coded data, and a backward decoder 109 starts to decode the coded data stored in the buffer 107 from the suffix of the coded data.

The forward decoder 108 determines that an error is detected, when a bit pattern, which does not exist in a forward code-word table 111, appears in the decoded data or when a decoded data having a bit number different from the bit number of the buffer 107 is decoded. Similarly, the backward decoder 109 determines that an error is detected, when a bit pattern, which does not existed in a backward code-word table 112, appears in the decoded data and when a decoded data having a bit number different from the bit number of the buffer is decoded.

The decoded-value determining part determines decoded values on the basis of a decoded result (a forward decoded result) obtained by the forward decoder and a decoded result (a backward decoded result) obtained by the backward decoder, to output a final decoded result.

FIG. 55 is a block diagram of the code-word table preparing part 101. The occurrence probability of source symbols is inputted to a stochastic model preparing part 23 to prepare a stochastic model, which is inputted to a code selecting part 21. The code selecting part 21 selects a code system having a shortest average code length from selectable code systems to transmit the selected result to a code-word forming part 22. The code-word forming part 22 forms code words of the code selected by the code-word selecting part 21.

In this sixth preferred embodiment, a method for designing a stochastic model is as follows. In the sixth preferred embodiment, a method for designing a generalized stochastic model of a high coding efficiency with respect to various probability distributions of source symbols will be described.

First, notation will be described.

θi: Information Source (i=1, . . . , n)

X: Source Symbols of Information Source X=(x 1, x 2, . . . , xm)

P(X|θi): Frequency Distribution of θi

As an example, a plurality of test images may be used as information sources, and the frequency distribution obtained by coding the test images may be considered.

A designed stochastic model Q(X) is derived by weighting and averaging the frequency distribution obtained by the plurality of information source. $\begin{matrix} {{Q(X)} = {{{w\left( {\theta \quad 1} \right)}{P\left( {X{\theta \quad 1}} \right)}} + \ldots + {{w\left( {\theta \quad n} \right)}{P\left( {X{\theta \quad n}} \right)}}}} \\ {= {\sum\limits_{i = 1}^{n}{{w\left( {\theta \quad i} \right)}{P\left( {X{\theta \quad n}} \right)}}}} \end{matrix}$

 w(θi): Weighting Factor w(θl)+ . . . +w(θ1)=1

In this case, it is a problem how to derive the weighting factor w(θi). When the information source θi is coded by Q(X), an ideal code length L(X|θi) is as follows. ${L\quad \left( {X{\theta \quad i}} \right)} = {\sum\limits_{i = 1}^{m}\quad {P\quad \left( {X{\theta \quad i}} \right)\quad \log \quad 2\quad \left( {Q\quad (X)} \right)}}$

In order to minimize the ideal code lengths L(X|θi) of the respective information sources on average, assuming that $\begin{matrix} {{{U(X)} = {\left( {1/n} \right){\sum\limits_{i = 1}^{n}{P\left( {X{\theta \quad i}} \right)}}}},} \\ {{M(X)} = {{- \left( {1/n} \right)}{\sum\limits_{i = 1}^{n}{\sum\limits_{i = 1}^{m}{P\left( {\left. {X{\theta \quad i}} \right)\log \quad 2\left( {Q(X)} \right)} \right.}}}}} \\ {= {\sum\limits_{i = 1}^{m}{{U(X)}\log \quad 2\left( {Q(X)} \right)}}} \end{matrix}$

When U(X)=Q(X), this function is minimum as follows.

w(θ1)= . . . =w(θn)=1/n

As another method for designing a stochastic model Q(X), a method for designing a stochastic model Q(X) by supposing the worst information source will be described.

When the information source θi is coded by Q(X), redundancy R(X|θi) is as follows. ${R\left( {{X\left. {\theta \quad i} \right)} = {{L\left( X \right.}\theta \quad i}} \right)} + {\sum\limits_{i = 1}^{m}\quad {P\left( {X\left. {\theta \quad i} \right)\log \quad 2\left( {{P\left( X \right.}\theta \quad i} \right)} \right)}}$

A weighting mean S(X) of these redundancy with respect to the respective information sources is a function indicative of a mutual information of event X and event θ as follows. $\begin{matrix} {{S(X)} = {\sum\limits_{i = 1}^{n}{{w\left( {\theta \quad i} \right)}R\left( \left. {X{\theta \quad i}} \right) \right.}}} \\ {= {\sum\limits_{i = 1}^{n}{{w\left( {\theta \quad i} \right)}{\sum\limits_{i = 1}^{m}{P\left( {\left. {X{\theta \quad i}} \right)\log \quad 2\left( {{P\left( {X{\theta \quad i}} \right)}/\left. {\sum\limits_{i = 1}^{n}{{w\left( {\theta \quad i} \right)}{P\left( {X{\theta \quad i}} \right)}}} \right)} \right.} \right.}}}}} \end{matrix}$

As a method for deriving the maximum value of this function, there is known Arimoto-Blahut's algorithm, which is disclosed in “An algorithm for computing the capacity of arbitrary discrete memoryless channels” (S. Arimoto, IEEE Trans. Inform. Theory, Vol. IT-18, pp.14-20, 1972), and “Computation of channel capacity and rate-distortion functions” (R. E. Blahut, IEEE Trans. Inform. Theory, Vol. IT-18, pp.460-473, 1972). By this algorithm or the like, it is possible to derive w(θi) (i=1, . . . , n) having the maximum S(X), i.e., the worst w(θi).

As methods for designing the stochastic model Q(X), although the method for minimizing the ideal code length on average and the method for supposing the worst information source on average have been described, a method for combining the above two methods to group information sources to prepare some stochastic models by the former method to use the latter method for the stochastic models may be applied.

The code selecting part 21 shown in FIG. 55 prepares Q(Y), which is obtained by sorting the source symbols X in order of probability in the stochastic models Q(X) prepared by the stochastic model preparing part 23. The code selecting part 21 also prepares F(Z), which is obtained by sorting the code lengths of the reversible codes prepared by the code forming part 22 in order of shorter length, to calculate $\sum\limits_{i = 1}^{m}{{{Q(Y)}{F(Z)}}}$

to select one of the minimum value to prepare a code-word table, in which source symbols correspond to code words.

As the codes formed by the code-word forming part 22, variable length codes are used, which are described in, e.g., Japanese Patent Application 7-89772 or 7-260383, which uses the weights of the code words and which can be decoded both in the forward and backward directions.

Seventh Preferred Embodiment

The seventh preferred embodiment of the present invention will be described below.

FIG. 56 is a block diagram illustrating a conception of a moving picture coding and/or decoding system, which incorporates the seventh preferred embodiment of a variable length coding and/or decoding system according to the present invention. In a moving picture encoder 709, data coded by a source encoder 702 are variable-length coded and multiplexed by a moving picture multiplexing part 703 to smoothed by a transmission buffer 704 to be transmitted to a transmission or storage system 705 as coded data. A coding control part 701 controls the source encoder 702 and the moving picture multiplexing part 703 in view of the buffer capacity of the transmission buffer 704. In a moving picture decoder 710, the coded data transmitted from the transmission or storage system 705 are stored in a receiving buffer 706 to be multiplex-separated and variable-length decoded by a moving picture multiplexing separating part 707 to be transmitted to a source decoder 708, so that the moving picture is finally decoded.

Additional syntax in the seventh preferred embodiment will be described. FIGS. 57A, 57B, 58A and 58B show syntax of a moving picture coding system in the moving picture multiplexing part 703 and the moving picture multiplexing separating part 707 in the seventh preferred embodiment. Coded data are separated into upper and lower layers, and synchronization intervals of the respective layers are set by synchronization patterns RM and MM. In the lower layer, ST denotes a stuffing code capable of being decoded in the backward direction as shown in FIG. 68. As shown in FIG. 69, an intraframe coding frame is separated into an upper layer, which has a part of mode information of macro blocks and INTRA DC, and a lower layer, which has the rest of the mode information and an AC-DCT coefficient information, to which reversible codes are applied. As shown in FIG. 70, an interframe coding frame is separated into an upper layer, which has a part of mode information of macro blocks and a motion vector information, and a lower layer, which has the rest of the mode information and an AC-DCT coefficient information, to which reversible codes are applied.

The coding and decoding of the upper and lower layers shown in FIGS. 57A through 58B are carried out by means of a moving picture multiplexing part shown in FIG. 59. These constructors are the same as those of a coding and/or decoding system in the fifth preferred embodiment. That is, although the basic constructions of the moving picture multiplexing part 703 and the moving picture multiplexing separating part 707 of FIG. 56 are the same as those shown in FIGS. 57A through 58B, the constructions of an upper-layer variable length encoder 801, a lower-layer variable length encoder 803, an upper-layer variable length decoder 805 and a lower-layer variable length decoder 806 are different from those in the second preferred embodiment. That is, out of data coded by the source encoder 702, the upper layer data indicated by, e.g., the syntax of FIGS. 57A or 58A, are variable-length coded by the upper-layer variable length encoder 801 to be transmitted to the multiplexing part 803. In addition, out of data coded by the source encoder 702, the lower later data indicated by, e.g., the syntax of FIGS. 57B or 58B, are variable-length coded by the variable length encoder 802 to be transmitted to the multiplexing part 803. The coded data of the upper and lower layers are multiplexed by the multiplexing part 803 to be transmitted to a transmission buffer 704.

In the seventh preferred embodiment, decoded-value determining parts 110 (shown in FIG. 37) in the upper-layer variable length decoder 805 and the lower-layer variable length decoder 806 determine decoded values on the basis of the forward decoded result obtained by a forward decoder 108, to output a final decoded result. In the error detection in the forward decoder 108 and the backward decoder 109 in the respective layers, when a bit pattern, which does not exist as code words, appears or when an error is detected by a check bit or the like, the position of the bit pattern or the error is regarded as a detected position, and when no error is detected by the above described determining method and when the number of decoded bits is not coincident with the bit number of coded data in the synchronization interval, the first decoding position is regarded as an error detected position.

Eight Preferred Embodiment

FIGS. 60 and 61 show examples of a source encoder 702 and a source decoder 708 in the eighth preferred embodiment of a coding and/or decoding system according to the present invention. In FIG. 60, an input picture signal is divided into macro blocks by means of a blocking circuit 401. The input picture signal divided into macro blocks is inputted to a subtracter 402, by which a difference between the input picture signal and a prediction picture signal is derived to produce a prediction residual signal. One of this prediction residual signal and the input signal outputted from the blocking circuit 401 is selected by a mode selecting switch 403 to be discrete-cosine-transformed by a DCT (discrete cosine transform) circuit 404. DCT coefficient data obtained by the DCT circuit are quantized by a quantizer circuit 405. The quantized data are divided into two parts, one of which is transmitted to a moving picture multiplexer 703 as a DCT coefficient information, and the other of which is sequentially processed by an inverse quantizer circuit 406 and an IDCT (inverse discrete cosine transform) circuit 407, the processes being inverse to those of the quantizer circuit 405 and the DCT circuit 404, to be added, by means of an adder 408, to the prediction picture signal inputted via a switch 411 to produce a local decoded signal. This local decoded signal is stored in a frame memory 409 and inputted to a motion compensation circuit 410. The motion compensation circuit 410 carries out the motion compensation between the input picture signal and the local decoded signal to derive a motion vector to produce a prediction picture signal. The derived motion vector information is transmitted to a moving picture multiplexer 703. A mode selecting circuit 412 determines a prediction system for coding the respective macro blocks, on the basis of information from the motion compensation circuit 410, to transmit the result to the moving picture multiplexer 703 as a mode information with quantization parameters and so forth. In FIG. 60, the output coded data are formed by grouping the DCT coding coefficient, the motion vector information and the mode information.

Referring to FIG. 61, the construction of an information source decoder 708 for decoding data coded in FIG. 60 will be described below. FIG. 61 shows an example of the information source decoder 708 corresponding to FIG. 60. In FIG. 61, the information source decoder 708 receives a mode information divided by a moving picture multiplexing separating circuit 707, a motion vector information, a DCT coefficient information and so forth.

In a mode determining circuit 504, to which the mode information is inputted, if the mode information is an INTRA, a mode selecting switch 505 is turned OFF, and the DCT coefficient information is inverse quantized by an inverse quantizer circuit 501 to be inverse discrete-cosine-transformed by an IDCT circuit 502 to produce a regenerative picture signal. This regenerative picture signal is stored in a frame memory 506 as a reference image and outputted as a regenerative picture signal. If the mode information is an INTER, the mode selecting switch 505 is turned OFF, and the DCT coefficient information is inverse quantized by the inverse quantizer circuit 501 to be inverse discrete-cosine transformed by the ICDT circuit 502. Then, the reference image is motion-compensated in the frame memory 504 on the basis of the motion vector information to be added in an adder 503 to produce a regenerative picture signal. This picture signal is stored in the frame memory 504 as a reference image and outputted as a regenerative picture signal.

Ninth Preferred Embodiment

Referring to FIG. 62, as an applied example of the present invention, an embodiment of an image transmitter receiver, to which the ninth preferred embodiment of a moving picture coding and/or decoding system incorporating a variable length coding and/or decoding system according to the present invention is applied, will be described below.

A picture signal inputted to a camera 1002 mounted on a personal computer (PC) 1001 is coded by means of a moving picture encoder 709 incorporated in the PC. The coded data outputted from the moving picture encoder 709 are multiplexed with other informations on voice and data to be radio-transmitted by a radio transmitter receiver 1003 to be received by another radio transmitter receiver 1004. The signal received by the radio transmitter receiver 1004 is divided into coded data and voice data of a picture signal. The coded data of the picture signal are decoded by means of a moving picture decoder 710 incorporated in a work station (EWS) 1005 to be displayed on the EWS 1005.

Similarly, a picture signal inputted by a camera 1006 mounted on the EWS 1005 is coded by the moving picture encoder 709 incorporated in the EWS 1005. The coded data are multiplexed with other information on voice and data to be radio-transmitted by the radio transmitter receiver 1004 to be received by the transmitter receiver 1003. The signal received by the transmitter receiver 1003 is divided into coded data and voice data of the picture signal. The coded data of the picture signal are decoded by means of the moving picture decoder 710 incorporated in the PC 1001 to be displayed on the PC 1001.

Tenth Preferred Embodiment

While the present invention has been grasped as a hardware construction of a moving picture coding and/or decoding system in the first through ninth preferred embodiments, the invention may be grasped as a recording medium for recording data or programs for use in a coding and/or decoding system in the above preferred embodiments. The tenth preferred embodiment of a recording medium for recording data or programs will be described below.

In an information source encoder 702 shown in FIG. 56, 8×8 blocks of DCT coefficients after quantization are scanned in the block's to derive LASTs (0: non-zero coefficient, which is not the last of the block, 1: non-zero coefficient of the last of the block), RUNs (the number of zero runs before the non-zero coefficient) and LEVELs (quantized value of the coefficient), which are transmitted to a moving picture multiplexing part 703.

A lower-layer variable length encoder 802 in the moving picture multiplexing part 703 has an INDEX table wherein INDEXs of code words (VLC_CODE) of reversible codes correspond to RUNs and LEVELs of non-LAST coefficients of INTRA (intraframe coding) shown in FIG. 66, an INDEX table wherein INDEXs of code words (VLC_CODE) of reversible codes correspond to RUNs and LEVELs of non-LAST coefficients of INTER (interframe coding) shown in FIG. 67, an INDEX table wherein INDEXs of code words (VLC_CODE) of reversible codes correspond to RUNs and LEVELs of common LAST coefficients of INTRA and INTER shown in FIG. 68, and a code-word table wherein code words correspond to the INDEX values shown in FIGS. 69 and 70.

Referring to a flow chart of FIG. 63, the operation of the lower-layer variable length encoder 802 will be described. First, on the basis of the mode information, the code-word table of the non-LAST coefficients and the LAST coefficients of the INTRA is selected when the INTRA is carried out, and the INDEX table of the non-LAST coefficients and the LAST coefficients of the INTER when the INTER is carried out (S101). Then, in order to code using the code-word table, (RUN, LEVEL) is compared with the maximum value R_max of the RUNs and the maximum value L_max of the LEVELs in the INDEX table, so that it is verified whether (RUN, LEVEL) exists in the INDEX table (S102).

If it exists therein, the INDEX table of FIGS. 66 through 68 is used to check whether the value of the INDEX is 0 (S104). If it is not 0, the code words of the INDEX in the code-word table of FIG. 17 are outputted. The last bit “s” of the code words in the code-word table denotes the sign of the LEVEL. When “s” is “0”, the sign of the LEVEL is positive, and when “s” is “1”, the sign of the LEVEL is negative (S105). When the value of the INDEX is 0 or beyond the range, ESCAPE codes continue as shown in FIG. 73 by coefficients, which do not exist in the code-word table, and 1 bit indicating whether it is a LAST coefficient and the absolute values of the RUNs and LEVELs shown in FIGS. 71 and 72 are fixed-length coded. To the prefix of the fixed-length coding part, “00001” of two escapes is added, and to the suffix, an escape code is also added. The code words, wherein the INDEX values in FIGS. 69 and 70 are 0, are escape codes. The last bit “s” of the VLC_CODE used as the ESCAPE code denotes the sign of the LEVEL. If the “s” is “0”, the LEVEL is positive, and if the “s” is “1”, the LEVEL is negative (S106).

As described above, if the INDEX table is used, it is possible to efficiently output code words without the need of search even if the ESCAPE codes are used. The lower-layer variable length decoder 802 has a decoded-value table shown in FIGS. 74 and 75, and operates on the basis of the INDEX values obtained by decoding variable length codes.

Referring to flow charts of FIGS. 64 and 65, the operation of the lower-layer variable length decoder will be described below.

FIG. 64 shows the decoding operation in the forward direction. First, variable length code are decoded in the forward direction (S201). Then, it is check whether the INDEX value obtained by decoding is 0 (S202). If it is not 0, the INTRA and INTER of the decoded-value table of FIG. 74 are selected on the basis of the mode information of the upper layer, to derive decoded values of the LAST, RUN and LEVEL (S203). Since it is an escape code when the INDEX value is 0, the subsequent fixed-length code is decoded to derive decoded values of the LAST, RUN and LEVEL (S204). Subsequently, the end ESCAPE code is decoded (S205). The sign of the LEVEL is positive when the last bit of the code word is “0”, and negative when it is “1” (S206).

FIG. 65 shows the decoding operation in the backward direction. First, the sign of the LEVEL is determined by the first bit of the code word. If it is “0”, the sign is positive, and if it is “1”, the sign is negative (S301). Then, the variable length code is decoded in the backward direction (S302). Then, it is checked whether the INDEX value obtained by decoding in the backward direction is 0 (S303). When the INDEX value is not 0, the INTRA and INTER in the decoded-value table of FIG. 74 are selected on the basis of the mode information of the upper layer, to derive decoded values of the LAST, RUN and LEVEL (S304). When the INDEX value is 0, it is an escape code, so that the subsequent fixed-length code is decoded to derive decoded values of the LEVEL, RUN and LAST (S305). Subsequently, the first ESCAPE code is decoded (S306). As described above, if the decoded-value table is used, it is possible to save the memory capacity and to efficiently carry out the bidirectional decoding even if the ESCAPE code is used.

The supplementary explanation of the decoding process in the tenth preferred embodiment will be given. That is, a decoded-value determining method when the syntax of the moving picture coding system in the moving picture multiplexing part 703 is syntax shown in FIGS. 57A through 58A will be described. First, a mode information 1 and a INTRA DC of the upper layer are decoded. If an error is found and the mode information 1 and the INTRA DC are not completely decoded, all the decoded values of macro blocks of a synchronization interval, in which an error occurs, are regarded as “Not Coded”. If the first frame is coded and the last frame does not exist, the macro blocks are colored in gray or a special color.

In the lower layer, when a mode information 2 can not be decoded due to an error, all the coded data of the lower layer are abandoned, and the decoded values of the upper layer are rewritten to be regarded as “Not Coded”, or indicated by only the INTRA DC. When AC-DCT coefficients are predicted in some of macro blocks of the INTRA mode, variable length codes can be decoded. However, since the prediction is carried out on the basis of the surrounding macro blocks, when the variable length codes can not be decoded in the surrounding macro blocks, the decoded values are regarded as “Not Coded”.

In the interframe coding frame, the mode information 1 and the motion vector of the upper layer are first decoded. If an error is founded and the mode information 1 and the motion vector can not be completely decoded, all the decoded values of the macro blocks of a synchronization interval, in which the error occurs, are regarded as “Not Coded”. If all can be decoded, it is verified that the synchronization interval MM exists. If it does not exist, all the decoded values of the macro blocks of the synchronization interval are regarded as “Not Coded”.

In the lower layer, when the mode information 2 and the INTRA DC can not be decoded due to an error, the coded data of the lower layer are abandoned, and the decoded values of the upper layer are rewritten by the indication of “Not Coded” or the indication (MC Not Coded) of only motion vectors from the last frame.

If the AC-DCT coefficients are predicted in some macro blocks of the INTRA mode, the variable length codes can be decoded. However, since the prediction is carried out on the basis of the surrounding macro blocks, when the variable length codes can not be decoded in the surrounding macro blocks, the decoded values are regarded as “Not Coded”.

FIG. 76 shows a detailed decoded-value determining method in the AC-DCT coefficient portion of the interframe coding frame. First, as shown in FIG. 76(a), when the ways to the positions (error detected positions) of a macro block, in which errors are detected in the forward and backward decoded results, do not overlap with each other, only the decoded results of a macro block, in which no error has been decoded, are used as decoded values, and the decoded results at the two error detected positions are not used. In addition, the decoded results of the upper layer are rewritten on the basis of the decoded results of the upper layer so that the INTRA macro block is directly indicated by the last frame and the INTRA macro block is indicated only by the motion compensation using the last frame.

As shown in FIG. 76(b), when the ways to the error detected positions overlap with each other in the forward and backward decoded results, the forward decoded results are used for decoded values before the macro block, in which the error has been detected in the forward decoded result, and the backward decoded results are used for decoded values after the macro block.

Alternatively, the backward decoded results may be preferentially used for decoded values before the macro block, in which the error has been detected in the backward decoded result, and the forward decoded results may be used for decoded values after the macro block.

As shown in FIG. 76(c), when errors are detected in the same macro block both in the forward and backward decoded results, the decoded values in the macro block at the error detected position are abandoned and are not used for decoded values. In addition, the decoded results of the upper layer are rewritten on the basis of the decoded results of the mode information of the upper layer so that the INTRA macro block is directly indicated by the last frame and the INTER macro block is indicated by only the motion compensation using the last frame, and the backward decoded results are used for the decoded values after the macro block.

As shown in FIG. 76(d), when an error is detected in the stuffing code and the decoding can not be decoded in the backward direction, the decoding is carried out only in the forward direction. When the error is detected, the decoded results of the upper layer with respect to the macro blocks after the error detected position are rewritten on the basis of the decoded results of the mode information of the upper layer so that the INTPA macro blocks are directly indicated by the last frame and the INTER macro blocks are indicated only by the motion compensation using the last frame.

While the decoded values have been determined every macro blocks in the decoded-value determining method of FIG. 76, the detected values may be determined every block or code word.

As described in the above preferred embodiments, a variable length coding and/or decoding system of the present invention requires smaller amounts of calculation and storage to be efficient. Specifically, the variable length coding and/or decoding system can be applied to a moving picture coding and/or decoding, and it is possible to provide an efficient moving picture coding and/or decoding system with smaller amounts of calculation and storage. 

What is claimed is:
 1. A moving picture decoding system, comprising: input means for inputting a first code string which is arranged in the forward direction from the prefix to the suffix, and a second code string which is arranged in the backward direction from the suffix to the prefix; and decoding means for decoding said first code string in the forward direction from the head to the end, and said second code string in the backward direction from end to the head.
 2. A moving picture decoding system as set forth in claim 1, comprises: input means for inputting code string which have been divided into a plurality of regions every frame to be coded; decoding means for decoding the code string of each of the regions supplied from said input means; and reordering means for reordering the data of each of the regions supplied from said decoding means, in correct order.
 3. A variable-length decoding system for decoding coding data of a variable-length code which is able to be decoded in either of the forward and backward directions, and in which synchronizing codes are inserted at regular intervals, said variable-length decoding system comprising: forward decoding means for decoding said variable-length code in the forward direction and for detecting an error in a code word of said variable-length code; backward decoding means for decoding said variable-length code in the backward direction and for detecting an error in a code word of said variable-length code; and decoded-value deciding means for deciding a decoded value on the basis of the decoded results of said forward decoding means and said backward decoding means, wherein said decoded-value decoding means decides a decoded value at a position in which said error is detected in accordance with the detected result of the error by said forward decoding means and said backward decoding means.
 4. A variable-length decoding system for decoding coding data of a variable-length code which is able to be decoded in either of the forward and backward directions, said variable-length decoding system comprising: forward decoding means for decoding said variable-length code in the forward direction; backward decoding means for decoding said variable-length code in the backward direction; and fixed-length code decoding means for decoding a fixed-length code, wherein when said variable-length code is decoded by said forward decoding means and said backward decoding means, if specific codes representative of the head and end of the said fixed-length code are decoded, the subsequent coding data are decoded by said fixed-length decoding means.
 5. A variable-length decoding system for decoding coding data obtained by coding an orthogonal transform coefficient, which has been produced by the orthogonal transform for each of blocks by means of a moving picture encoder, into a variable-length code which is able to be decoded in either of the forward and backward directions, said variable-length decoding system comprising: forwarding decoding means for decoding said variable-length code in the forward direction; backward decoding means for decoding said variable-length code in the backward direction; and deciding means for deciding the last of a block on a basis of an appearance of a code word representative of the last orthogonal transform coefficient of the block when said forward decoding means decodes said variable-length code, and for deciding the head of a block by a code word representative of the last orthogonal transform coefficient of the last block.
 6. A moving picture decoding system, comprising: an input for inputting a first code string which is arranged in the forward direction from the prefix to the suffix, and a second code string which is arranged in the backward direction from the suffix to the prefix; and a decoder for decoding said first code string in the forward direction from the head to the end, and said second code string in the backward direction from end to the head.
 7. A variable-length decoding system for decoding coding data of a variable-length code which is able to be decoded in either of the forward and backward directions, and in which synchronizing codes are inserted at regular intervals, said variable-length decoding system comprising: a forward decoder for decoding said variable-length code in the forward direction and for detecting an error in a code word of said variable-length code; a backward decoder for decoding said variable-length code in the backward direction and for detecting an error in a code word of said variable-length code; and a logic circuit for deciding a decoded value on the basis of the decoded results of said forward decoder and said backward decoder, wherein said logic circuit decides a decoded value at a position in which said error is detected in accordance with the detected result of the error by said forward decoder and said backward decoder. 